WO2003014715A1 - Spr interferometer - Google Patents
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- WO2003014715A1 WO2003014715A1 PCT/GB2002/003543 GB0203543W WO03014715A1 WO 2003014715 A1 WO2003014715 A1 WO 2003014715A1 GB 0203543 W GB0203543 W GB 0203543W WO 03014715 A1 WO03014715 A1 WO 03014715A1
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- interferometer
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N21/00—Investigating or analysing materials by the use of optical means, i.e. using sub-millimetre waves, infrared, visible or ultraviolet light
- G01N21/17—Systems in which incident light is modified in accordance with the properties of the material investigated
- G01N21/41—Refractivity; Phase-affecting properties, e.g. optical path length
- G01N21/45—Refractivity; Phase-affecting properties, e.g. optical path length using interferometric methods; using Schlieren methods
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N21/00—Investigating or analysing materials by the use of optical means, i.e. using sub-millimetre waves, infrared, visible or ultraviolet light
- G01N21/17—Systems in which incident light is modified in accordance with the properties of the material investigated
- G01N21/55—Specular reflectivity
- G01N21/552—Attenuated total reflection
- G01N21/553—Attenuated total reflection and using surface plasmons
Definitions
- the present invention relates to optical interferometers .
- Interferometers are used in many fields but the present invention is particularly, though not exclusively, concerned with interferometers whose applications include the detection of optical phase changes due to surface binding under surface plasmon resonance (SPR) conditions and to the detection of binding at multiple, discrete sites in the surface using the phase images thereby obtained.
- SPR surface plasmon resonance
- SP Surface Plasmons
- SPR is used in molecular binding detection analysis where typically molecules to be tested are deposited on the thin film and potential binding agents are passed in a solution or gas over the rear face of the thin film. If binding occurs between a molecule and a binding agent under SPR conditions the refractive index at that point will change and can be detected.
- molecular binding detection analysis include, but are not limited to, measuring the expression levels of genes and proteins in biological samples, determining the functions of genes and proteins, identifying actual or potential therapeutic drugs and other molecules, determining the biological effects of actual or potential therapeutic drugs and other molecules. These applications can be used in biological research activities, in discovery and development of drugs, and as diagnostic tests.
- a Mach Zehnder device has been configured to measure SPR phase changes produced by variations in the refractive index of a gas local to the measurement surface.
- a major disadvantage of this type of device, particularly with respect to routine laboratory use, is that it requires four independent components: two beam splitters and two mirrors, one of which is the resonant surface in the case of the SPR configuration.
- the arrangement is relatively bulky and, more critically, the output is sensitive to sub-wavelength relative displacements of these components and hence very small mechanical and environmental perturbations.
- Figure 1 is a diagrammatic cross section through the known (Kretschmann) configuration of optics for illuminating a surface under SPR conditions.
- Figure 2 shows a graph illustrating the non-linear resonant characteristics in the intensity (I) and phase domain ( ⁇ ) of the light reflected from the surface in Figure 1 over the range for which surface plasmons are generated.
- Figure 3 is a diagram showing the basic configuration of an interferometer in an embodiment in accordance with the present invention.
- Figure 4 is a diagram showing part of a second embodiment of the present invention.
- Figure 5 is a diagram showing the collimation of an extended illumination source.
- Figure 6 is a diagram showing part of the interferometer in which a bi-prism is introduced to generate an angular shear between the interfering wavef onts .
- Figure 7 is a diagram showing part of an interferometer in which a lens is used to superimpose the sheared interfering wavefronts in the plane of the detector array.
- Figure 8 is a diagram showing part of the interferometer in which a displacement is applied to a bi prism in order to generate a relative phase step between the interfering wavefronts .
- Figure 9 is a diagram showing part of the interferometer in which a displacement is applied to single angle prism in order to generate a relative phase step between the interfering wavefronts.
- Figure 10 is a diagram showing an optical configuration by which a translation of the source causes the direction of propagation of the collimated wavefront to rotate about the optical axis of the collimating lens;
- Figure 11 is a diagram showing an array of individually collimated light sources
- Figure 12 is a diagram showing telecentric illumination optics based on an array of sources
- Figure 13 is a diagram showing one arrangement of the reference and measurement surfaces in which the thickness of the coating in the reference region is such that it does not support resonance and that in the measurement region is at a resonant thickness.
- the diagram also shows a binding layer conformably coated on both the reference and measurement films;
- Figure 14 is a diagram showing an alternative arrangement of the reference and measurement surfaces in which both have the same resonant coating thickness.
- the binding layer conformably coats the measurement surface only;
- Figure 15 is a block diagram showing a signal processing unit
- Figure 16 is a perspective view of one practical embodiment.
- Figure 17 is a diagram showing an implementation of the invention using waveguides .
- This comprises a prism 1 , a slide in the form of an optical flat glass plate 2 optically contacted to the base of the prism 1 and a thin metallic film 3.
- the film 3 is coated with a chemical layer 3 ' to which are bound molecule ligands.
- the chemical layer may, for example, consist of carboxymethyl dextran and typical probe molecules include antibodies, enzymes and proteins.
- the angle of the prism 1 depends upon its refractive index that of the optical flat and the medium in contact with it. For the high refractive index glass required for resonance in contact with water it is typically 60°.
- the film 3 can for example, be of gold or silver and has a thickness in the range typically 20nm to 50nm depending on the sharpness of the resonance i.e. the angular width ⁇ r required.
- the metal film 3 acts as a two dimensional environment for surface plasmons (SP). These are, as already mentioned, the collective oscillations of free electrons which are confined to move in the film and which are excited into oscillation by external electromagnetic radiation coming from the high refractive index medium provided by the prism 1 and the optical flat 2.
- the radiation is in the form of an input beam of polarised light from a suitable light source 4. To maximise the resonant component of the reflected light the light beam is polarised in the plane of incidence, (i.e. it is p polarised).
- the output light field is converted to an electronic signal by a suitable optoelectronic detector 5 and output data is generated from output electronic signal by appropriate circuitry connected to the detector (i.e. 6 as shown in a specific implementation in Figure 3 )
- Figure 2 shows the variation in the intensity and the phase of the light reflected from the surface in Figure 1 over the angular resonant range ⁇ r for which resonant surface plasmons are generated.
- the angular position of the resonant intensity minimum ⁇ p for a given film material is a sensitive function of the refractive index of the medium in direct proximity with the surface. Changes to molecules bound to the surfaces due to interaction and binding with other modules affect the local refractive index and therefore modulate the position of minimum shown in Figure 2.
- the present invention is concerned with avoiding the limitations of these known methods and involves Phase domain ⁇ imaging.
- the reason for this is that the phase ⁇ varies approximately- linearly with respect to the resonant angle ⁇ r and hence a small angular shift of the resonance ⁇ p causes a phase shift ⁇ where:
- a ⁇ A ⁇ r (1) ⁇ ⁇
- ⁇ requires that the arrangement shown in Figure 1 be incorporated in an interferometer such that the wavefront reflected from the resonant surface interferes with a reference wavefront.
- the fringe shift in the resultant interference pattern due to changes in local refractive index as the result, for example, of molecular binding can then be detected.
- this embodiment incorporates the same basic configuration of prism 1, optical flat 2 , polarised light source 4 , a photosensitive detector and electronic circuitry 6.
- the detector 5 ' is pixelated so that it can generate two dimensional images for subsequent recording and display.
- the signal processing circuitry 6 also has to operate in a manner different from the prior art configuration.
- the film 3 covering the base face of the prism is varied so that the base face is divided with two areas 7 and 8.
- Area 7 is treated so as to be non-resonant and thereby provide a reference area. This can be achieved by increasing the thickness of this film area to a non-resonant value .
- Area 8 is the measurement area and is created in a manner similar to the film of the prior art SPR configuration in Figure 1.
- the reference and measurement regions have the same resonant thickness but with only the measurement region being coated with a suitable molecular binding coating.
- the differential phase is proportional to the binding that occurs when a buffer fluid or analyte containing the binding molecules is flowed simultaneously over the reference and measurement surfaces.
- the embodiment of Figure 3 has additional components in the form of a parallel faced optical flat 9 in the path of the beam of light from the polarised light source 4 and beam shaping optics 10.
- the beam shaping optics 10 will be described in greater detail hereinafter.
- the optical flat 9 is mounted normally parallel to the base of prism 1.
- the detector 5 ' of this embodiment is pixelated so as to generate an image of the combined beam reflected from the respective reference and measurement areas.
- Fourier Transform and Phase Stepping techniques may be conveniently used to measure the relative phase of the reference and measurement beam as a function of pixel coordinate in the 2D array and are described later.
- the local phase changes will correspond to those induced by changes in the refractive index at the surface due, for example, to molecular binding.
- This mode of operation requires that the illumination and viewing optics of the specific forms discussed later be used.
- a 2D phase image of the SPR binding is thereby generated.
- the measurement surface may be patterned with an array of discrete sites each having different binding properties (e.g. ligands) and the response to a given molecule (e.g. a specific protein) determined from the previously described phase image.
- a beam of light from the source 4 and optics 10 is partially reflected from the front face of the optical flat 9 at a point 11 to form a reference beam R and the transmitted beam is reflected from the rear face of optical flat 9 at 12 to form a measurement beam M.
- the beams R and M are incident on the areas 7 and 8 respectively at points 13 and 14.
- the reference and measurement beams R and M recombine at point 15 by being reflected from the rear face of optical flat 9 at 16 and the front face of optical flat 9 at point 15.
- the measurement beam M generates surface plasmon resonance at point 14 but, depending on the arrangement used, either no resonance or binding refractive index change is generated at point 13.
- the combined beam is incident on the pixelated detector 5' via viewing optics 18 so as to generate an image which is analysed by the circuitry shown at 6.
- An additional optical element 50 may be incorporated in the interferometer to modify the relative phase of the reference and measurement beam in accordance with the requirements of the phase measurement technique.
- Figure 4 shows a second embodiment which in principle operates in exactly the same manner as the first embodiment.
- an additional prism 9' similar to prism 1 but which acts as a reference prism as the base of this second prism is treated in a manner similar to reference area 7 so as to be non-resonant.
- a plane polarised reference light beam from a light source 4 impinges on prism 9' to be reflected at point 21 to form a reference beam R and the measurement beam from source 4 impinges on prism 1 to be reflected at point 22 so as to generate surface plasmon resonance and to provide as before a measurement beam M.
- the reference and measurement beams will generate a two dimensional image on the pixilated detector 5 ' .
- phase of the resonant measurement beams is measured as a function of the spatial co- ordinates as detected by the pixilated detector array 5 ' and can be used by the processing circuitry 6, as the previous embodiment, to establish an image of binding events over an array of discrete binding sites 8 in the measurement areas .
- the stability of the two embodiments described above results from the commonality of the beam division/recombination and reference/measurement optical elements. Spatially uniform relative displacements of these components have a common effect on the path lengths of the reference and measurement beams and accordingly do not cause relative phase shifts. A relative rotation of the components generates a spatially uniform phase change which may be subtracted when detecting localised phase variations.
- a further advantage of the preferred configurations is that any phase shifts not associated with resonant binding that are common to the surface that embodies the reference and measurement zones cancel out automatically.
- the first requirement is that the angular divergence ⁇ of the illumination light field has to be small with respect to the angular width of the resonance ⁇ r in order to minimise the convolutive blurring of ⁇ with respect to ⁇ and the resultant loss of sensitivity d ⁇ /d ⁇ . It also has to be spectrally narrow band in order to prevent equivalent blurring in the spectral domain.
- the object plane i.e. measurement surface
- the composite reference and measurement surface is effectively a plane, internal mirror.
- the light reflected from individual elements of the measurement surface hence propagate as corresponding elements of the reflected wavefront.
- any lens used in the output path of the interferometer need only serve the significantly less demanding function of modifying the geometry of the interfering wavefronts.
- ⁇ ⁇ l f (2) ⁇ is reduced to the minimum value by using a source with minimum radius ⁇ and extending the focal length f of an optimal lens form to the maximum practical value.
- the source may consist of:
- (b) is coupled ( ⁇ 5 ⁇ m) .
- the filter (32) may follow the polariser (31) and collimating lens 30 as shown in Figure 5.
- Lasers (b) , (c) are preferred to a white light source (a) because the optical power throughput of the latter is significantly less than the former due to the low coupling efficiency of light from the extended source through the small pin-hole and attenuation by the narrow pass band spectral filter (typical spectral width lOn ) .
- minimum values of ⁇ and hence convolutive resolution loss are attainable using a laser source.
- the general disadvantage of a laser for imaging applications is that the scatter and diffraction of laser light at random micro defects in the optical surfaces generates image noise. This is due to the high spatial and temporal coherence lengths Xc and Lc of the light field where,
- Coherent noise impairs intensity domain images of SPR binding for which it has been found necessary to use the lower coherence pin-hole arrangement (a) with the attendant loss of optical power and image signal to noise ratio.
- phase domain processing is intrinsically less sensitive to such noise due to operation in either a narrow band of spatial frequency (Fourier Transform method) or an intensity independent mode (Phase Stepping method).
- I r) a ⁇ r) + c(r).e iVc r) - c ⁇ r e i ⁇ k r (5)
- the 2-D Fourier transform of the intensity profile consists of a complex function that has three main local maxima of its absolute value. These occur one at the DC level, and two from the carrier frequency (i.e. one at f 0 and one at -f 0 )
- the 3-lobed function in frequency space is then translated such that the lobe at f 0 is moved to DC.
- An apodisation function is then applied so that the other lobes of the function are suppressed.
- the inverse Fourier transform is then taken of this data, which leaves only one term from the complex intensity expression above. Taking natural logs of the system, and noting that phase can be extracted from the polar form of complex expressions we find,
- phase can be extracted by taking only the imaginary part of the output of the inverse Fourier Transform.
- the spacing of the fringe described by equations 4,5 needs to be nominally 0.2 times the spatial resolution at which it is required to measure phase variations. In a typical high throughput application the spatial resolution is expected to be of the order lOO ⁇ . Hence a detector plane fringe spacing of about 20 ⁇ m is required assuming unity magnification.
- Fringe fields with this geometry may be generated by introducing an angular shear between the reference and measurement wavefronts.
- the arrangement shown in Figure 6 may be used.
- the reference and object beams are passed through the adjacent facets of a small angle bi-prism 50 after reflection from the elements 7 and 8 of the test region and prior to recombination of the interferometer output.
- This prism arrangement is preferred because it is intrinsically insensitive to vibration and does not require that the simple planar geometry of the basic interferometer be modified.
- An angular shear 2 ⁇ (rads) is thereby introduced between the beam where,
- Figure 7 shows how a lens 51 of focal length f in the output beam path following the combination point 15 shown in Figure 3 may be used to superimpose the interfering beams in the plane of the pixelated detector 5 ' .
- q is the ratio of the input beam diameter to that in the plane of the detector.
- the path difference over which uniform fringe contrast needs to exist for total path differences is typically 0.2mm i.e. the coherence length of the source should be of the order 1 to 10 mm for which stable, single mode operation is required to ensure high fringe stability.
- the combination of near diffraction limited plane wave illumination and high spatial and temporal coherence that results from the use of laser source causes the fringe and image planes to be non-localised. Consequently a fringe field is superimposed upon the measurement plane structure in any plane before or after the lens in which beam overlap occurs.
- the fringe spacing depends on q (equation 8) which is a function of this plane.
- the introduction of a lens results in a plane for which precise beam superposition occurs.
- the detector 5 ' shown in Figure 7 is located in this plane.
- the calculation defined by this equation is performed for each pixel in the array and a 2D phase image thereby generated.
- Precise phase steps may be generated by translating the bi-prism 50 ( Figure 6) as shown in Figure 8.
- an actuator 53 translates the prism 50 in its plane by a known distance d.
- This introduces a relative path difference, p between the reference and measurement wavefront where, p 2nd ⁇ and (12)
- n refractive index of the prism
- o- must be selected such that the fringe spacing generated by the shear intrinsic to the arrangement can be resolved by the detector and the required path difference p compatible with the displacement range of the actuator.
- the latter may consist of a piezo actuator with integral position transducer and a typical displacement range of lOO ⁇ m.
- An alternative method for introducing the phase shift without the introduction of an angular shear between the wavefronts is shown in Figure 9.
- the beam which it is required shift in phase is passed through two matched prisms 54 and 55 having the same prism angle ⁇ .
- the phase shift is introduced by translating one of the prisms in a distance d relative to the other in a direction parallel to its inclined face.
- the translation of the source 4 by a distance d from 1 to 2 in the focal plane of the collimating lens 30 as shown in Figure 10 may be used.
- This results in the central axis of the collimated beam being rotated by an angle ⁇ where ⁇ d/f.
- the focal plane illumination source may consist of an optical fibre linked to a remote light source and attached to a displacement transducer.
- Figure 11 of the accompanying drawings shows a variant in which a plurality of similar optical illumination systems are provided with parallel optical axes.
- Figure 5 shows one such system it will be appreciated that there can be an array of light sources 4, 4 lf 4 2 , ... 4 n , each of which have an associated lens, polariser and if necessary narrow band pass filter.
- Use of such an array of light sources enables an increased part of the measurement areas of the embodiments described to be utilised substantially increasing the amount of analysis which can be carried out by a single interferometer.
- this shows a twin lens telecentric system as an alternative to a lens array.
- the telecentric system results in an illumination beam consisting of a parallel pair of rays with covergence angle ⁇ ' for the two sources 42 and 43.
- the two lenses 44 and 45 have f 1 and f 2 as their focal lengths and the two light sources 42 and 43 separated by a distance ⁇ are located in the focal plane of lens 44.
- the arrangement can be extended to multiple sources which may be any of the light sources already described.
- the system is constrained by the following two equations which follow from the Lagrange invariant:
- This telecentric system is provided with a stop 46.
- FIG 15 shows the typical constituent elements of the signal processing unit 6 shown in Figure 3.
- a synchronisation pulse indicating, for example, the injection of binding molecules is delivered by the unit 61.
- a typical example of a frame grabber is that available on the market as "Coreco Imaging PC-DIG-LVDS" (TM) .
- This data is processed by a digital processor 63 (PC, DSP etc..) using algorithms 64.
- Data is displayed by 65 which may in practice be a VDU.
- Figure 16 shows a typical practical configuration of the system with some of the elements shown in previous figures indicated.
- the optical flat 2 and the metal film 3 (which may carry the chemical attachment layer 3 ' ) can be permanently adhered to the relevant face of the prism 1.
- the optical flat 2 and film 3 are formed as a removable slide which can be suitably mounted so as to be tightly held against and index matched to the face of the prism 1.
- the slide can be removed and a freshly prepared slide introduced, thus increasing the rate of testing.
- Figure 17 shows an equivalent waveguide configuration of the system.
- light from a light source 70 is coupled via a bi-directional waveguide beam coupler 71 into a linkage waveguide 71" which is coupled into a second bi-directional waveguide coupler 72.
- the outputs from the latter couples light into the waveguide measurement arm 73 (M) and waveguide reference arm 74 (R) of the sensor.
- the measurement arm is configured to be resonant by modification of the waveguide geometry.
- the upper surface of the waveguide may, for example, be made planar and coated with gold of appropriate thickness.
- Light passing through the waveguides 73 and 74 - is reflected from the respective waveguide end facets 73 ',74' and interferes on recombination at the directional coupler 72. It is then coupled back via 71' and 71 to the detector 75 where the light field is detected and the phase shifts measured.
- the measurement and reference waveguide can be placed in very close proximity. Under these conditions non-resonant effects due to temperature changes, vibration, etc... are, to a very good approximation, common to both waveguides. The measured phase changes are therefore due primarily to surface plasmon resonance effects in the measurement channel.
- the path difference between the reference and measurement channels is made greater than the coherence length of the light source.
- Figures 13 and 14 show configurations of the embodiment of Figures 3 and 4 for this purpose.
- the substrate 2 is optically contacted with the prism 1 and coated with a thin metallic film 3 carrying a chemical attachment layer 3 ' .
- the thickness of this metallic coating of the reference region 7 is such that it does not support resonance and that in the measurement region 8 is at resonant thickness.
- a second thin chemical attachment film 3' conformably coats the metallic film in the measurement area.
- Discrete binding sites B ⁇ to B n which may consist of probe molecules such as antibodies, or other molecules with specific affinities, are deposited on the chemical attachment film 3' in the measurement area 8.
- the angle of incidence of the illumination is adjusted such that the composite surface 3 , 3 ' , B x to B n is at peak resonance with the incident light field in the presence of an analyte fluid which is passed over the binding sites B in a suitable conduit 50.
- the reference phase is recorded in this state and molecules P such as proteins are then introduced into the analyte and a change in phase at a binding site used to detect the molecular binding of P to B at that site.
- the interferometer may be used for monitoring the interactions between various types of molecules, where one of those molecules (hereafter referred to as the "probe” molecule) is immobilised to the surface of the array 3. In this manner, probe molecules are tested for their ability to bind other molecules - hereafter known as “target” molecules.
- Probe molecules are localised at particular defined sites on the surface of the array.
- the entire array may consist of many separate probe sites (Bx to B n ), containing identical or different probe molecules .
- Multiple similar or different molecules, built on or attached to each other, can also be used to detect binding of molecules in the sample.
- the surface carrying probe molecules may be exposed to a sample solution. Binding may occur between probe molecules immobilised on the array surface, and target molecules in the same solution.
- the interferometer described will enable the detection of binding events that occur between probe molecules localised on the array and target molecules in the solution.
- the method and apparatus just described has a number of advantages over the prior art. In particular it allows many probe molecules to be studied simultaneously; it enables binding of a target molecule to be detected without the need for labelling the target molecule with another chemical such as a fluorescent, chemiluminescent or bioluminescent tag, or with radioactivity; and it enables binding between probe molecules and target molecules to be monitored in real time.
- Detection of binding may allow a measurement of the quantity of target molecule present in the sample. It may also allow measurement of the kinetics and affinity of the interaction between the probe and the target molecules .
- the embodiments described are also suitable for detecting many combinations of interactions between types of molecules that include but are not limited to: proteins, antibodies, nucleic acids (including DNA, RNA . and derivatives thereof), other biological molecules (including but not limited to carbohydrates, lipids, vitamins, hormones, peptides) and chemicals (including but not limited to chemical therapeutic compounds and drugs ) .
- the interferometer may detect interactions between any of these types of molecules as probe, and any of these types of molecules as target.
- the target molecules may be present in a sample solution of which they are the only solute or component.
- the target molecules may also be present in a complex sample with many constituents in addition to the target molecules .
- the amount of binding between probe molecules and target molecules detected by the interferometer can be used to determine the quantities of those proteins in the original sample.
- Detecting levels of proteins in biological samples may be used to gain insight into gene function amongst other applications. Changes of protein levels that correspond to changes in the nature of the biological preparation, such as the onset of disease, can be used to reveal functional correlations between proteins, genes and biological phenomena such as disease, response to drugs (toxicology) and all the molecular and cellular processes of life.
- Functional information about genes and proteins may be used to select genes and proteins as potential targets for the development of drugs to intervene in disease functions. Functional information about genes and proteins can also be used to understand and predict the activity of therapeutic drugs in affecting disease process, in causing toxicity, and in other pharmalogical and biological effects. Functional information about genes and proteins can also be used to gain understanding of the basic processes of life, in health and in disease.
- Information about the association between protein levels and different cellular or biological states can be used to generate diagnostic tests that determine the existence of that particular cellular or biological state - e.g. disease.
- the interferometer described here can itself be used as a device for diagnosing disease, or monitoring other conditions in patients or in animals, such as pregnancy.
- the amount -of binding between probe molecules and target molecules detected by the interferometer can be used to determine the degree of interaction between the probe molecule and the target molecules .
- the amount of binding between probe molecules and target molecules detected by the interferometer can be used to determine the degree of interaction between the probe molecule and the target protein.
- Molecules identified as binding to proteins may be useful as therapeutic compounds if the protein is involved in a particular disease.
- the probe molecules are multiple different proteins, and the target molecules are actual or potential therapeutics (including but not limited to chemical compounds, biochemical compounds, antibodies or proteins), and the sample is a preparation containing one or more therapeutics
- the amount of binding between probe molecules and target molecules detected by the interferometer can be used to determine the degree of interaction between the probe proteins and the target therapeutics.
- Information about the interaction between therapeutics and proteins can give insight into the function of the therapeutics, which can be used in the development of therapeutics.
- this information may include but is not limited to information regarding the toxicity of the therapeutic, the pharmacological behaviour of the therapeutic, the metabolism, excretion, absorption of the therapeutic, as well as the mechanism of action of the therapeutic in affecting a disease state.
- the interferometer described here can itself be used as a device for diagnosing disease, or determining other conditions in patients or in animals.
- the device will be especially appropriate for making diagnoses when many factors are involved, or for carrying out multiple diagnostic tests on a single sample in one reaction by using many probe molecules as appropriate.
- monitoring this type of in vitro reaction can be useful in conducting basic research into the mechanisms of life in health and disease, as well as carrying out specific assays to understand disease processes and other biological processes relevant to development of therapeutics and diagnostics . Additionally monitoring this type of in vitro reaction can enable real time feedback control mechanisms, where the constituents of the reaction vessel are adjusted and controlled automatically, according to information received from the interferometer device.
- Monitoring bioreactors can enable real time feedback control mechanisms, where the constituents of the reaction vessel are adjusted and controlled automatically, according to information received from the interferometer device.
- a device based on the interferometer can be used to monitor the condition of patients in real time.
- the device may be especially useful in situations that require measurement of multiple different indications at the same time.
- a device based on the interferometer can be used to monitor the presence and the levels of components and contaminants in foods and other substances . This has applications both for process control as well as quality assessment of products .
- a device based on the interferometer can be used for the detection and measurement of substances in water, for example in re-processing plants and reservoirs.
- Real time detection of binding between modules may be used to analyse the kinetics of the interaction between those molecules .
Abstract
Description
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Application Number | Priority Date | Filing Date | Title |
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DE60215018T DE60215018T2 (en) | 2001-08-06 | 2002-08-01 | SPR INTERFEROMETER |
EP02751365A EP1415140B1 (en) | 2001-08-06 | 2002-08-01 | Spr interferometer |
US10/485,716 US7084980B2 (en) | 2001-08-06 | 2002-08-01 | SPR interferometer |
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Application Number | Priority Date | Filing Date | Title |
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GBGB0119062.8A GB0119062D0 (en) | 2001-08-06 | 2001-08-06 | Interferometer |
GB0119062.8 | 2001-08-08 |
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WO2003014715A1 true WO2003014715A1 (en) | 2003-02-20 |
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PCT/GB2002/003543 WO2003014715A1 (en) | 2001-08-06 | 2002-08-01 | Spr interferometer |
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US (1) | US7084980B2 (en) |
EP (1) | EP1415140B1 (en) |
DE (1) | DE60215018T2 (en) |
GB (1) | GB0119062D0 (en) |
WO (1) | WO2003014715A1 (en) |
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US7084980B2 (en) | 2006-08-01 |
EP1415140A1 (en) | 2004-05-06 |
DE60215018T2 (en) | 2007-05-03 |
EP1415140B1 (en) | 2006-09-27 |
DE60215018D1 (en) | 2006-11-09 |
US20050052655A1 (en) | 2005-03-10 |
GB0119062D0 (en) | 2001-09-26 |
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